JP4576003B2 - Wireless communication service provider search method and wireless communication apparatus - Google Patents

Description

Background of the Invention
The present invention relates to communication, and more particularly to communication in a multiple service provider environment.
FIG. 1 shows a part of the radio spectrum. The frequency range 10 centered at about 800 MHz is historically known as the cellular frequency range, and the frequency range 12 centered at about 1900 MHz is a newly defined frequency range, Personal Communications Service (PCS). Is related to. Cellular and PCS frequency ranges are each divided into two parts. There is an uplink portion 14 in the cellular frequency range 10, which is used for communications sent from a mobile communication device to a base such as a cellular base. The portion 16 of the cellular frequency range 10 is used for downlink communication, i.e. communication sent from the cellular base to the mobile communication device. Similarly, the portion 18 of the PCS frequency range 12 is used for uplink communications, i.e. communications sent from the mobile communications device to the base. The portion 20 of the PCS frequency range 12 is used for downlink communication, i.e. communication sent from the base to the mobile communication device.
Each of the above frequency ranges is usually divided into a number of bands and is usually associated with different service providers. For cellular frequency range 10, frequency bands 30 and 32 are dedicated bands “a” for uplink and downlink communications, respectively. In certain areas, cellular providers are assigned a frequency band “a” for mobile communications. Similarly, another cellular provider in the same region is assigned frequency bands 34 (uplink) and 36 (downlink), which are dedicated bands “b”. The frequency spectrum allocated to the service provider is divided so that mutual communication does not interfere and the service can be provided in the same area even if there are two service providers separately. Recently, the US government publicly sold the PCS frequency spectrum to service providers. Similar to the cellular frequency range, the PCS frequency range is also divided into several bands, and different service providers can use specific licensed frequency bands within specific regions. Each PCS band is referred to as A, B, C, D, E, F. Band A includes an uplink band 50 and a downlink band 52. Band B includes an uplink band 54 and a downlink band 56. Band C includes an uplink band 58 and a downlink band 60. The uplink and downlink bandwidths of A, B, and C bands are each about 30 MHz. Band D includes an uplink band 62 and a downlink band 64. The band E includes an uplink band 66 and a downlink band 68. Similarly, the band F includes an uplink band 70 and a downlink band 72. The uplink and downlink bandwidths of the D, E, and F bands are each about 10 MHz. It should be noted that with the cellular frequency band and the PCS frequency band, different wireless communication service providers can simultaneously operate eight operators in a specific region.
Each of the different cellular and PCS bands includes an uplink and downlink bidirectional control channel and a communication channel. In the case of the analog cellular band, there are 21 control channels for both the “a” and “b” bands. Each control channel comprises an uplink portion and a downlink portion. The control channel carries various information such as SOC (system operator code), SID (system identification code), paging information, call setup information, and other overhead information such as information regarding registration of the mobile communication system. The portion of the cellular band spectrum that is not occupied by the control channel is used for the communication channel. Communication channels carry voice communication or data communication, and each channel comprises uplink and downlink communication links. There are currently several cellular communication standards. An analog standard known as EIA / TIA553 is defined on top of the AMPS (Advanced Mobile Phone Service) standard. This standard supports 21 analog control channels (ACC) and hundreds of analog voice (or traffic) channels (AVC). A recent new standard is the EIA / TIA IS54B standard, which supports dual mode operation. Dual mode operation means having either an analog voice / traffic channel or a digital traffic channel (DTC) in addition to the analog control channel. AVC or DTC is used for actual communication, and ACC is used, for example, to transfer information related to call setup, service provider awareness, and other overhead or system information.
A recent new standard, the EIA / TIA IS135 standard, supports communications covered by both analog and dual mode cellular, and has a totally digital communication scheme. The all-digital communication scheme is designed for PCS frequency bands AF and cellular frequency bands “a” and “b”. Using this standard, a digital traffic channel (DTC) and a digital control channel (DCCH) are possible. In the case of DTC, not only voice communication or data communication is performed, but also a digital channel locator (DL) is transmitted to the DTC. With DL, a mobile communication device locked to DTC looks up DCCH using DL information and obtains information such as SOC, SID, paging and other system overhead information carried on the digital control channel Is possible.
When a mobile communication device such as a mobile phone attempts to register with a service provider, it first locks on the control channel and reads information such as SOC and SID. If the SOC and / or SID correspond to the service provider of the user's communication service contract, the telephone can be registered with the service provider's mobile communication system via the uplink control channel.
FIG. 2 shows a US map showing cities such as Seattle, Chicago, and Washington, DC. For example, in Seattle, it is assumed that a license for frequency band A is given to an SOC (service operator code) 001 having SID43, and a license for frequency band C is given to SOC003 having SID37. In Chicago, it is assumed that a license for frequency band C is given to SOC001 having an SID equal to 57, and a license for frequency band B is given to SOC003 having SID51. In Washington DC, it is assumed that a license for frequency band “a” is granted to SOC001 having SID21, and a license for frequency band A is granted to SOC003 having SID17. It should be noted here that the same SOC may be in several different regions, although with different frequency bands. It should also be noted that the same SOC is associated with different SIDs in each region, and that different service providers have different SIDs in the same region. Now, assume that a particular subscriber of a wireless telecommunications service has a contract with a service provider having SOC001. The subscriber will want to use a system with SOC001. This is because the usage fee is lower for the subscriber. The subscriber would like to use band A when in Seattle, band C when in Chicago, and band “a” when in Washington, DC. However, problems occur for wireless communication service subscribers in the above situation. When a subscriber moves from one region of the country to another, the phone makes a call to find a “home” service provider, ie, a service provider with which the subscriber has previously contracted. For example, if a subscriber travels from Seattle to Chicago and attempts to make a call in Chicago, the phone examines the different bands of the frequency spectrum, recognizes the service operator with code number 001, and finds the desired service provider.
To find a particular service provider, the phone may have to search for both “a” and “b” bands for the cellular band and all six bands for the PCS band. Recall that there are 21 different ACCs in each of the cellular bands “a” and “b”. It may be necessary to check as many as 42 ACCs to find an ACC that can obtain an SOC or SID. Furthermore, locating a specific SOC or SID in the PCS bands A-F is a particularly time consuming process. The digital control channel (DCCH) contains the SOC and SID, but is not assigned to a specific frequency within a specific PCS band. As a result, it is necessary for the mobile communication device to search the entire spectrum of each PCS band and search for the DCCH or search for an active DTC with a digital channel locator that guides the mobile communication device to the DCCH. As mentioned above, the process of locating a particular service provider is laborious and may require several minutes of ordering time.
Summary of invention
In one aspect of the present invention, a method is provided for locating a specific or desired communication service provider in an environment having multiple service providers. After power-up, a mobile communication device, such as a cellular telephone, checks the most recently used control channel and determines if the optimal service provider is available on that channel. If the optimal service provider is not available or the channel is not available, the mobile communication device searches the frequency spectrum in a predetermined order to find the optimal or acceptable service provider.
In another aspect of the invention, the search for the frequency spectrum is performed according to a predetermined order and an order that is changed based on information entered by the mobile communication device vendor or mobile communication device user. In yet another aspect of the invention, the predetermined order of spectrum search for locating service providers is updated using air programming. In yet another aspect of the present invention, the predetermined order of search is performed based on the past operation history of the mobile communication device.
In yet another aspect of the present invention, the frequency band search order is performed based on supervision and management of a search process on the communication device side, and information for establishing a “personal use frequency history” of a specific user is stored in the communication device. Remembered.
[Brief description of the drawings]
The accompanying drawings, which are described in and constitute a part of this specification, illustrate preferred embodiments of the invention and, together with the description of the invention, illustrate the principles of the invention.
FIG. 1 shows a frequency spectrum used for wireless communication.
FIG. 2 shows some of the service areas in the United States.
FIG. 3 is a block diagram of the mobile communication device.
FIG. 4 is a flowchart showing a spectrum search routine.
FIG. 5 is a flowchart showing an overall spectrum search routine.
FIG. 6 is a flowchart showing a periodic search routine.
FIG. 7 is a flowchart showing a routine for searching for the strength of the received signal.
FIG. 8 shows a search schedule.
FIG. 9 shows a search schedule ordered by the registration history.
FIG. 10 shows a priority list of service providers.
FIG. 11 shows an alphanumeric display shown on the mobile communication device.
Detailed description of the drawings
FIG. 3 shows a block diagram of a mobile communication device such as a cellular telephone or a personal communication device. The mobile communication device 10 includes a transceiver 12 and transmits and receives signals from the antenna 11. The mobile communication device 10 is controlled by the control system 14. The control system 14 can comprise a microprocessor or a microcomputer. The control system 14 uses the memory 16 to store a program to be executed or to store information input by a user, a seller, a communication service provider, or a manufacturer. Information such as user preferences, user phone numbers, preferred service provider lists, frequency search schedules are stored in memory 16. The memory 16 may include storage devices such as random access memory (RAM), read only memory (ROM) and / or programmable read only memory (PROM). The user communicates with the control system 14 through the keypad 18. The control system 14 communicates with the user through the display 20. The display 20 displays information such as status information and items such as telephone numbers input with the keypad 18. Audio information transmitted from the mobile communication device 10 is received via the microphone 22, and the audio information received by the mobile communication device 10 is reproduced by the speaker 24 to the user.
After the power is first turned on, the mobile communication device finds a service provider and registers with the service provider. Referring back to FIG. 1, service providers are located in multiple frequency bands of the radio spectrum. To locate a service provider, the communication device searches the spectrum to find a service provider. The communication device examines the received service provider code, for example, SOC (Service Operator Code) or SID (System Identification Code) and determines whether the service provider is optimal, preferred or prohibited as a service provider. decide.
FIG. 4 illustrates the process or program that the control system 14 executes to find a preferred service provider. After power-on, step 30 is executed to initialize the non-optimal flag by erasing the flag. Step 32 determines whether the last provider, i.e., the service provider used before powering down, was the optimal service provider. This determination is made by checking the last service provider's SOC or SID and determining if that service provider's SOC or SID corresponds to the optimum service provider's SOC or SID. The last service provider's SOC or SID and the list of optimal and preferred service providers are stored in memory 16. If at step 32 it is determined that the previous service provider is not optimal, a global spectrum search is performed. If the last service provider was optimal, step 34 is executed and the control system 14 attempts to lock the service provider's control signal. If the lock is not successful, an overall spectrum search is performed, indicating that the control channel is no longer available or out of range. If the lock is successful, step 36 is executed. In step 36, it is determined whether the control channel contains the SOC or SID of the optimal service provider. Again, this is determined by matching the SOC or SID from the control signal with a list of the optimal service provider's SOC or SID. If the SOC or SID does not belong to those of the optimal service provider, an overall spectrum search 33 is performed, and information about what frequency band that had the non-optimal SOC or SID is forwarded to the overall search routine 33 And unnecessary re-searching of this part of the spectrum is avoided. If it is determined in step 36 that there is an optimum service provider, the communication device is registered with the service provider. Step 40 is an idle step where the control system 14 simply monitors the service provider's control channel and awaits communication system overhead information, paging information indicating an incoming call, and the like. In the idle state 40, a timer is activated to allow a cycle search with low capacity when the phone is currently registered with a non-optimal service provider. This situation can occur when an overall spectrum search yields a preferred service provider but is not optimal. Periodically, for example, every 5 minutes, step 42 is executed to determine if a non-optimal flag has been set. If the non-optimal flag is not set, the control system 14 returns to the idle step 40. If the non-optimal flag is set, step 42 leads to the execution of a periodic search routine 44 where a search is made to find the optimal service provider. If the optimal service provider is found by the periodic search routine 44, the non-optimal service provider flag is cleared and the mobile communication device is registered with the optimal service provider, while the periodic search routine 44 is executed. Next, the mobile communication device enters an idle state by executing step 40. If the optimal service provider is not found in routine 44, control system 14 returns to the idle state by performing step 40.
FIG. 5 shows a flowchart of an overall spectrum search routine 33 executed by the control system 14. In step 60, it is determined whether the last control channel used by the mobile communication device was a personal communication service (PCS) related control channel, that is, a control channel of frequency bands A to F. If the last control channel is not a PCS control channel, step 62 is executed. In step 62, it is determined whether the mobile communication device can lock or receive and decode the last used ACC (analog control channel). If the mobile communication device has successfully locked to the last ACC, step 64 is executed. If the mobile communication device cannot lock to the last ACC, step 66 is executed. In step 66, RSS (Reception Signal Strength Scan) is executed. The role of this step is to tune the mobile communication device to each of the 21 ACCs associated with the last used ACC cellular band and attempt to lock onto the strongest received signal. In step 68, it is determined whether a lock has been made. If no lock is obtained at step 68, a predetermined search schedule is executed to find a service provider. If a lock is obtained at step 68, step 64 is executed and the SOC or SID obtained from the control channel is checked against the list of optimal SOCs or SIDs. In step 70, if the received SOC or SID is associated with an optimal service provider, step 72 is executed and the mobile communication device clears the non-optimal flag and is registered with the communication service provider, then the step of FIG. The idle state is entered by executing 40. If the optimal service provider's SOC or SID is not received at step 70, step 74 is executed and the memory 16 stores what was the frequency just searched. Step 78 is performed after step 74, after step 68 if no lock is obtained, or after step 60 if the last control signal was from the PCS frequency band. In step 78, the search schedule is downloaded using the master search schedule. When downloading the search schedule in step 78, the previously searched frequency bands are removed from the download schedule to avoid re-searching the already searched bands. For example, the band searched in the search routine discussed in connection with FIG. 4 and the cellular band discussed in connection with step 74 are excluded from the search schedule. After loading the modified search schedule, the search pointer is initialized and the pointer is applied to the first band recognized by the modified search schedule. The first band recognized on the modified search schedule is searched for received signal strength (RSS) in the RSS routine of step 79. For the bands “a” and “b”, the ACC having the strongest signal is selected. In the case of the PCS band, that is, the bands A to F, the 2.5 MHz portion of each band is searched in the 30 kHz section. The mobile communication device tunes to the strongest signal above the minimum threshold, eg, -110 dBm, within the 2.5 MHz examined. In step 80, it is determined whether the signal is valid, i.e., whether the signal meets one of the above standards. If not valid, the search pointer is incremented at step 96, and if the signal is valid, step 82 is executed. In step 82, it is determined whether the signal is ACC. If the signal is ACC, the SOC or SID is decoded at step 90. If the signal is not ACC, step 84 determines whether the received signal is a digital traffic channel (DTC) or a digital control channel (DCCH). If the signal is DCCH, the SOC or SID is extracted at step 90. If a determination is made that the received signal is a DTC, step 86 is performed, the DL (Digital Channel Locator) is extracted, and the location of the DCCH associated with the received DTC is recognized. In step 88, the mobile communication device tunes to the strongest DCCH of the digital control channel recognized in DL. In step 90, the SOC or SID of the received DCCH is extracted, and in step 91, it is determined whether the SOC or SID is associated with the optimal service provider. If the SOC or SID is associated with an optimal service provider, step 92 clears the non-optimal flag and step 93 registers the mobile communication device with the service provider. After step 93, the communication device enters the idle state of step 40 of FIG. If it is determined in step 91 that the SOC or SID does not belong to those of the optimal service provider, step 94 is executed, and the SOC or SID is stored in the memory 16 along with the spectral position of the SOC or SID control channel. And the SOC or SID indicates that it is at least a preferred service provider and not an undesirable or prohibited service provider. In step 96, the search pointer that recognizes that a band is being searched is incremented by one to indicate what is the next band in the search schedule. In step 98, it is determined whether the pointer has reached the end of the search schedule. If the end of the search schedule has not been reached, step 79 is executed and, as discussed above, the received signal strength search (RSS) routine is repeated once again, after the last frequency band has been searched. Step 100 is executed. In step 100, the mobile communication device is registered with the best stored SOC or SID, ie the SOC or SID that was at least associated with the preferred service provider. The best service provider can know what is stored by checking the stored SOC or SID against a list of preferred SOCs or SIDs. The list of preferred SOCs or SIDs includes an optimal SOC or SID and a preferred list of preferred SOCs or SIDs. In this case, the higher priority is preferred for registration. The items on the list also include SOCs or SIDs that are used only in emergencies (eg, 911 emergency calls) or that are undesirable or prohibited when the user enters with an ignore command. After registering with the service provider in step 100, step 102 is executed and a non-optimal flag is set, then step 40 of FIG. 4 is executed and the mobile communication device enters an idle state.
It should be noted here that the search operations of FIGS. 4 and 5 can be performed in a simplified manner. Referring to FIG. 4, the control system 14 executes step 33 after step 30, and steps 32, 34, 36, and 38 can be skipped at any time. Referring to FIG. 5, the control system 14 initiates an overall spectrum search at step 78, and steps 60-74 can be skipped at any time.
FIG. 6 shows a flowchart for the periodic search routine executed by the control system 14. At step 120, it is determined whether a periodic search flag has been set. If the periodic search flag is not raised, step 122 is executed to flag the periodic search and initialize the search schedule. Initialization is done by loading the master search schedule into the search schedule used by the periodic search routine. However, the currently received frequency band is not included in the search schedule used by the periodic search routine. Step 122 also sets a pointer to the first band of the search schedule. In step 124, a received signal strength search (RSS) routine is performed. Similar to step 79 of the overall spectrum search routine of FIG. 5, step 124 is a PCS and cellular band RSS routine in the search schedule. In the case of a cellular band search, 21 ACCs are searched using a received signal strength search. That is, the transceiver tunes to the strongest ACC. In the case of PCS frequency band search, as discussed above, each band is divided into approximately 2.5 MHz parts, and each part is searched in 30 kHz sections. The strongest signal of the minimum threshold value within the 2.5 MHz portion, for example, −110 dBm or more, is selected. In step 126, the selected signal is examined to determine if the signal is valid against one of the previously referenced standards. If not valid, step 144 is performed, and if the signal is valid, step 129 is performed. In step 129, it is determined whether the signal is ACC. If the signal is ACC, step 130 is executed and the SOC or SID is extracted. If the signal is not ACC, step 132 is executed. Step 132 determines whether a DTC signal has been received. If the signal is not a DTC signal (and thus the signal is a DCCH signal), step 130 is performed and the SOC or SID is extracted from the DCCH signal. If at step 132 it is determined that a DTC has been received, then step 134 is executed to extract the DL so that it can be tuned to DCCH. In step 136, a received signal strength search is performed on the DCCH and the strongest signal is selected. Step 130 is then executed to extract the SOC or SID from the signal. In step 138, it is determined whether the SOC or SID is an optimal SOC or SID. If the SOC or SID is optimal, step 140 clears the non-optimal flag and in step 142 registers the mobile communications device with the service provider associated with the optimal SOC or SID. Next, step 40 of FIG. 4 is executed to enter an idle state. If step 138 determines that the SOC or SID is not from the optimal service provider, step 144 is performed. In step 144, the search pointer is incremented by one and the next band is searched. In step 146, it is determined whether all search schedules have been completed. If the schedule is not complete, step 40 is executed and the mobile communication device can return to the idle state. If step 146 determines that the search schedule is complete, step 148 clears the periodic search flag, then step 40 is executed and the mobile communication device can enter an idle state.
FIG. 7 shows a flowchart of an RSS routine, that is, a received signal strength search routine. This routine is performed, for example, in step 79 of FIG. 5 or step 124 of FIG. Step 170 determines whether the band being searched is one of the “a” or “b” cellular bands. If a cellular band is being searched, step 172 is performed, 21 ACCs are searched to determine which is the strongest, and the strongest ACC is tuned by the transceiver 12 under control of the control system 14. Then exit from the RSS routine. If step 170 determines that the cellular band has not been searched, step 178 tunes the transceiver 12 at the beginning of the first 2.5 MHz band of the PCS band being searched. Step 178 also erases the scratch pad memory location in memory 16. The scratch pad is used to record the amplitude (intensity) and position of the received signal. In step 180, it is determined whether the signal being received is greater than a threshold. If the signal is greater than the threshold, step 182 is performed, and if the signal is not greater than the threshold, step 184 is performed. In step 182, it is determined whether the received signal strength is greater than the signal strength value stored in the search scratchpad. If the signal is not large, step 184 is executed. If the signal is large, step 186 is executed and the current signal strength is stored in the search scratchpad along with the received signal position in the spectrum. In step 184, the transceiver 12 is tuned to a frequency 30 kHz higher than the previously tuned frequency. In step 188, it is determined whether the new frequency exceeds the 2.5 MHz band currently being searched. If the new frequency does not exceed the 2.5 MHz band, step 180 is executed and the received signal strength is again checked against the signal strength (amplitude) stored in the search scratchpad. If it is determined in step 188 that the increment by 30 kHz exceeds the 2.5 MHz band being searched, step 190 is performed. In step 190, the transceiver 12 is tuned to the signal position marked on the search scratchpad. If the signal is valid, it can be decoded and the RSS routine is exited. If the signal is not valid (eg, the signal does not conform to the reference standard above), it cannot be decoded and step 192 is performed. In step 192, the transceiver is tuned to the beginning of the next 2.5 MHz band in the currently searched PCS band. Step 194 determines whether the new 2.5 MHz band exceeds the currently searched PCS band. If the new increment exceeds the PCS band being searched, the periodic search routine is exited. If the PCS band being searched for does not exceed the 2.5 MHz increase, step 196 is executed. In step 196, the search scratchpad containing the signal strength measurement and signal position information is erased and prepared to search for another band. After step 196, step 180 is performed as described above.
FIG. 8 shows a master search schedule. The master schedule is used to initialize the search schedule used in the above search routine. The master search schedule is stored in a memory device such as the memory 16. The master search schedule can be initially programmed by the mobile communication device manufacturer, distributor or user. Note that the first position in the search schedule is without a left program. If left is blank, the blank is ignored when initializing the search schedule for the search routine. The first location is preferably programmed in the band where the user's home service provider is located. For example, if the service provider with which the user has a service contract has the SID where the user lives most or the license to operate in the PCS band B in the region, the band B becomes the first slot of the master search schedule. To program. For example, if band B is programmed into the first slot, the slot containing band B first is blank. This avoids searching the same band twice. Note also that the user can change the master search schedule through the keypad 18. Furthermore, the master search schedule can be reprogrammed using signals received from the wireless communication channel. For example, the ability of a mobile communication device to receive a new program for a master search schedule can be limited so that it is received only from a service provider that transmits a home SID and selective SOC. When a service provider sends a predetermined code, it is possible to ask for programming (air programing) sent by communication. It is desirable to limit the programming sent in communication by using code, home SID and / or selective SOC to avoid unintentionally or undesirably changing the master search schedule. The programming sent in communication can be incorporated using, for example, logical subchannels of the digital control channel. This logical subchannel is capable of transmitting data sent to a specific mobile communication device and receiving data such as confirmation data from the mobile communication device.
When initializing a search schedule using a master search schedule, it is also possible to prioritize the first position in the master search schedule, for example, in other frequency bands based on previous history of using a mobile communication device . For example, the first location searched for can be the location where the phone was last hung up (power off) or the location where the phone was last hung up (power on).
The frequency band search schedule can also be defined based on search process management performed on the mobile communication device side. In this method, the mobile communication device 10 provides, creates and maintains a table in the memory 16 for the counter associated with each frequency band in the master search schedule. Each time a mobile communication device receives a service from a preferred provider while using communication, the counter value associated with the frequency band is incremented by one to store information for establishing a “personal use frequency history” for the user. Go. Next, the mobile communication device uses these counter values to change the frequency band search order of the master search schedule.
FIG. 9 shows a table stored in memory 16 and provides a counter associated with each frequency band in the master search schedule of FIG. Based on the counter values in the table, the frequency band with the highest number of successful registrations as defined by the associated counter value follows the home frequency band in the master search schedule. Thereafter, each frequency band whose counter is not zero continues from the highest to the lowest according to the counter value. A frequency band with a counter value of zero follows a non-zero entry (entry) according to the first defined order.
In a preferred embodiment, the counter associated with each frequency band should store a finite number of registrations, for example 10 times, and minimize the storage requirement in memory 16. In addition, the stored counter value can be indicated by a time-weighted registration and a weighted recent registration. Use of the counter value weighted with time in this way is useful for optimizing search efficiency.
It is understood that the previously discussed programming method requires resetting the master search schedule, which may lead to situations where the search order may be redefined and the counter value set back to zero. is there.
FIG. 10 shows a table stored in the memory 16 that defines the SOC and SID of the optimal service provider and the SOC and SID of the preferred service provider. SOCs and SIDs with the lowest numbers are preferred over service providers with the highest priority and higher numbers and therefore lower priority. For example, a priority 2 SOC or SID is preferred over a priority 5 SOC or SID. The table may include SOCs or SIDs that are undesirable or prohibited. In the case of a prohibited SOC or SID, it is possible to connect to this prohibited SOC or SID when making an emergency call, for example a 911 emergency call, or when the user enters with an ignore command Is desirable. The table of FIG. 10 can be programmed by the manufacturer, the dealer when the phone is purchased, or the user. Also, the program of the table of FIG. 10 can be performed using communication using the same restrictions as those used when programming the master search schedule via communication.
The category of the multiple service provider can be recognized by checking the SID or SOC broadcast on the control channel with the entries (entries) in the table of FIG. These categories are
(1) Home: a preferred service provider, usually a service provider with which the user has a service contract. Once a mobile communication device is registered with a home service provider or gets a control channel, the mobile communication device does not seek service on any other frequency band.
(2) Partner: A partner of a home service provider. Once a mobile communication device is registered with a partner service provider or obtains a control channel for it, it does not seek service in any other frequency band.
(3) Preference ... A service provider whose home service provider has a preferential handling amount and / or service contract. The mobile communication device registers with the preferred service provider only if the home or partner service provider is not found. If certain situations occur, for example when the control channel changes or periodically, the mobile communication device searches for other frequency bands for the home or partner service provider.
(4) Prohibited ... A service provider that is never used under normal circumstances.
(5) Neutral: A service provider not listed in the SID or SOC described in the table of FIG. A mobile communication device registers with a neutral service provider only if no home, partner, or preferred service provider is found. If certain situations occur, for example when the control channel changes or periodically, the mobile communication device searches for other frequency bands for the home, partner or preferred service provider.
Although the present invention has been described with reference to preferred embodiments, the language has been used as a language for description and not for limitation. Accordingly, various modifications may be made within the scope of the following claims without departing from the true scope and spirit of the present invention in a broad aspect. For example, a “character display” stored in the memory 16 can be displayed on the mobile communication device to recognize a particular service type, while the mobile communication device can be placed in idle, ie, standby mode. The character display can be programmed or changed as part of activation by communication or programming by communication, as previously discussed. In an example in which XYZ is a home service provider, the character display unit is as follows, for example.
(1) Home ... "XYZ"
(2) Partner: “XYZ Partner”
(3) Preference ... "XYZ preference"
(4) Neutral: “Available”
In the existing standard, it is possible to broadcast the character part on the control channel and display it on the mobile communication device when it is idle, ie, in a standby state. For example, if the mobile communication device used by the XYZ subscriber is in the ABC market, the phone may display “ABC”. However, in the system described herein, the home service provider can control the mobile communication device to display “XYZ” as shown in FIG. Furthermore, it is also possible to update the character part according to market demands.

Claims (15)

In a method for a communication device to search for a wireless communication service provider in a plurality of service provider environments,
Storing a frequency search schedule comprising a plurality of frequency bands in a predetermined order;
For each frequency band of the frequency search schedule, storing a count indicating the number of registrations, which is the number of times a service has been received from a service provider in the frequency band ;
Modifying the order of at least some frequency bands of the plurality of frequency bands in the frequency search schedule based on a count of the most recent registrations for each frequency band ;
Examining the frequency bands in the modified order specified in the frequency search schedule until an acceptable service provider's existing frequency band is found;
A method for searching for wireless communication service providers in a plurality of service provider environments. A method as recited in claim 1, wherein, characterized by counting the number of registrations by counter provided corresponding to each frequency band for storing the count. The counter corresponding to the frequency bands that have been registered in the frequency search schedule, the method according to claim 2, wherein the further comprising the step of incrementing when registration of the frequency bands. The step of examining frequency bands, the method according to claim 1, wherein characterized in that it comprises the step of examining a frequency band last used by the communication device first. The step of examining frequency bands, the method according to claim 1, wherein characterized in that it comprises the step of examining frequency bands is sequentially in the frequency search schedule is constant first. The method of claim 1, further comprising modifying a frequency search schedule using information transmitted over the wireless interface. The method of claim 1, further comprising modifying a frequency search schedule using information from the keypad. The step of examining the frequency bands, until out find existing frequency bands of the service provider acceptable a permissible frequency signal strength, characterized in that it comprises a step of examining frequency bands in the order specified by the frequency search schedule The method of claim 1. The method of claim 1, wherein the predetermined order is based on a contractual relationship between at least some service providers in a plurality of service provider environments. Setting a first position of a frequency search schedule to a frequency band corresponding to a specific service provider;
Blanking the frequency band corresponding to the specific service provider set at the first position, which is set at a position other than the first position of the frequency search schedule ;
The method of claim 1, further comprising: In a method for a communication device to search for a wireless communication service provider in a plurality of service provider environments,
Storing a frequency search schedule comprising a plurality of frequency bands in a predetermined order;
For each frequency band of the frequency search schedule, and storing the number of times that has been serviced shown to count the number of registrations is from the service provider at that frequency band,
Incrementing a count corresponding to a frequency band of the frequency search schedule in time weighted increments upon registration of the frequency band ;
Based on the registration number of the count of each frequency band, the steps of orderly at least some of the frequency bands of a plurality of frequency bands in the frequency search schedule,
By examining a plurality of frequency bands in the order erected by the order in the step of orderly, the steps of examining a frequency band to out find existing frequency bands of acceptable service provider,
A method for searching for wireless communication service providers in a plurality of service provider environments. A wireless communication device for searching for a wireless service provider in a plurality of service provider environments,
A memory for storing a frequency search schedule having a plurality of frequency bands in a predetermined order;
For each frequency band of the frequency search schedule, a counter that stores a count indicating the number of registrations that is the number of times a service is received from a service provider in the frequency band ;
At least some of the frequency bands, and ordered in the order in which the most recent is corrected based on the registration number of the count of each frequency band in the counter, there is a frequency band of acceptable service provider of the plurality of frequency bands in the frequency search schedule A processor that examines multiple frequency bands in the modified order specified in the frequency search schedule until it finds
A wireless communication apparatus comprising: The wireless communication apparatus according to claim 12, wherein the predetermined order is based on a contract relationship between at least some service providers in a plurality of service provider environments. Wherein the memory, the radio communication apparatus according to the counter in the range 12 claims, characterized in that the store. Processor is further a first position within the frequency search schedule, and sets the frequency band corresponding to a particular service provider, is set to a position other than the first position of the frequency search schedule, the first The wireless communication apparatus according to claim 12, wherein a frequency band corresponding to a specific service provider set in the position is made blank.

Images